H2020 Europe´s research and innovation program has identified as one key societal challenge the smart green and integrated transport. In this context the Clean Sky programme aims at developing and demonstrating competitive and environmentally friendly technology for the aeronautic sector The Clean Sky2 ENGINES Integrated Technology Demonstrators (ITD) will demonstrate developed technologies at a whole engine level. Therefore, a set of new engine components have to be developed and manufactured, one of them is a Turbine Rear Frame (TRF).
The demands on reliability of this part are very high due to the combination of high thermal (around 700ºC) and structural loads. The main material characteristics to be considered are creep, mechanical properties at room and high temperature and weldability. During the engine lifetime cracking is major concern and TRF´s have to be inspected over time, overhauled, tested and repaired and this supposes not only a problem of enhanced costs, but also presents a mayor safety issue. Nowadays the alloys commonly used for the manufacturing of these parts are weldable nickel base superalloys.
It should be also noted that the TRF components and maintenance cost are an important issue as frames represent 16.3% of the total engine weight and around 15% of its total cost [1]. Furthermore, engine maintenance accounts for 35-40% of the total aircraft maintenance costs, (see section 2). Material replacements due to parts wear out represent about 60-70% of this percentage
In the HiperTURB project it is envisioned to improve weldability of a number of commercially available superalloys. This will be achieved by tailoring the solidification structure acting on the local cooling rate in the part (simulations tool, chillers, directional solidification etc.), performing inoculation and minor chemistry modifications, adapting the thermal processing and developing the welding process for the new alloys. Alloy and heat treatment development will be aided by microstructure simulation tools.
